CZ32847U1 - Plug-in and slide-out device for connecting and disconnecting optical and / or electrical connectors - Google Patents

Description

Plug-in and pull-out devices for connecting and disconnecting optical and / or electrical connectors

Technical field

The invention relates to an insertion and withdrawal device for connecting and disconnecting optical and / or electrical connectors. The retractable and retractable device comprises a guide frame with support holes in which the plug-in element is inserted and retracted by means of grooves and rails, and to the front wall of the plug-in element there is a locking mechanism equipped with a control lever, gear rods and cams each. is provided with a support tip and a stop tooth. The locking mechanism is equipped with a locking slider with a locking element.

BACKGROUND OF THE INVENTION

Patent CZ 304 640 B6, owned by SQS Fiber Optics et al., Nová Paka, CZ, which is also the applicant of the present invention, describes a plug-in device for connecting optical and / or electronic connectors in connector housings. The device comprises a plug-in element which slides into the guide frame. The guide frame has support holes in its side walls for receiving the support elements of the plug-in element. The plug-in element has a front wall equipped with a locking push-in mechanism.

The locking mechanism has, at one end thereof, a first pair of rotating cams arranged one above the other on the first end post. Each cam is provided with a stop tooth and a support tip. To each cam is attached a gear rod that extends substantially over the entire width of the locking mechanism.

The locking mechanism has, at its opposite end on the other end post, a control lever, which comprises two superimposed stop teeth and support points. The locking mechanism is equipped with a locking slider with a locking element.

The advantage of this plug-in device for sliding the plug-in element into the guide frame is that it transfers the subjective action of the insertion from the operator to the control lever, thereby eliminating any human error such as a sharp and strong insertion of the plug-in element into the guide frame. The subsequent protection against damage to the less visible rear mechanical parts of the guide frame by applying excessive pressure to the front of the plug element by bringing the rear parts of the support points of the plug element against the rear of the guide frame support holes can also be considered to be beneficial.

The drawback of this plug-in device is that it guarantees a uniform insertion of the plug-in element into the guide frame by actuating the control lever only until the connectors located at the rear of the plug-in element begin to press against the connectors located at the rear of the frame. At this point, the resilient elements of the connector connections (e.g., springs, sealing rubber, etc.) begin to compress, and as a result, forces occur against the plug element. The design of the locking mechanism is asymmetrical. As a result of this asymmetry in the design of the locking mechanism, it may happen that the side of the plug element on which the cams with support tips are not pushed as deep as the other side on which the support tips are directly part of the control lever. This is due to the fact that while the front of the support tips on the lever pushes against the front parts of the support tips holes on the guide frame with a force transmitted through only one pivot bearing, the front parts of the free cam support tips push against the front parts of the support tips holes on the other side. the guide frame by means of a lever transmission, which is formed by the pivotal bearing of the control lever, and in addition also by the draw bars which are connected to the cams and the lever by means of pivotal connections. Because on each pivot joint, both the drawbar and the control levers,

There is a certain tolerance of the produced parts, and since each stressed part is subject to a certain degree of elastic deformation, it is also not clear in advance what the final force distribution between the connector sleeves on the plug element and the frame will be with respect to the different types of connector connections used. then it is practically impossible to determine in advance how much the insertion of one side of the plug element will differ from the other. Accordingly, it is problematic to determine the required length of the rods so as to provide the necessary engagement of the front parts of the free cam support spikes so that the two lateral sides of the plug element are equally inserted into the guide frame in the closed position. The asymmetrical design of this mechanism is also unstable to temperature effects such that the depth of insertion of one side of the plug element relative to the other, in the closed position of the mechanism, will vary depending on the ambient temperature.

A further disadvantage of this design of the locking mechanism is that the control lever, as the only readily accessible element for pulling the plug-in from the guide frame, is located at one end of the plug-in locking mechanism of the plug-in. there is a certain risk that the pull-out plug-in element will jam.

The essence of the technical solution

Said drawbacks will eliminate or substantially reduce the insertion and withdrawal devices for connecting and disconnecting the optical and / or electrical connectors according to the preamble of claim 1 of the present invention, characterized in that the locking mechanism is equipped with rotary cams with its own axes of rotation at both ends. in this case, the cams, each with a stop tooth and a support tip, are coupled to a control lever disposed therebetween by means of gear rods. The locking mechanism has a control lever whose axis of rotation is located between the axes of rotation of the cams and is parallel to them. The cam axes define a plane at a distance s from the axis of rotation of the control lever, the distance s being a perpendicular line between the defined plane and the axis of rotation of the control lever.

The main advantage of the present invention is the positioning of the control lever between opposed cams, more precisely, the positioning of the control lever axis between the axes of opposed cams, which ensures that the connector housing of the plug element and the connector housing of the guide frame are evenly seated. or electrical connectors. The parallelism of the axis of the control lever with the axes of rotation of the two cams simplifies the design of the insertion and withdrawal device and its functionality. The plane defined by the cam axes and at a defined distance s from the axis of the control lever assists in a better structural function by being substantially parallel to the front and rear walls of the plug-in element. The locking slider arrangement according to the technical solution represents an optimal construction solution for the positioning of the control lever and cams. The detent mechanism is provided with a detent slider provided with a finger grip for operator control on the side facing the open position of the control lever and on the opposite side with a locking element for securing the closed position of the control lever when sliding the plug into the guide frame with defined axial connection of optical and / or electrical connectors a pluggable element with optical and / or electrical guide frame connectors.

The design according to the present invention represents a great improvement over the prior art, in particular the closest CZ 304 640 B6, while still retaining all its other advantages. The retractable and retractable locking mechanism according to the present invention is designed so that the insertion depths of the side walls of the plug-in element in the guide frame do not depend not only on mechanical, vibration or temperature influences, but also on elastic deformations of stressed parts of the closing mechanism. This equipment thus ensures the correct functioning of the operating systems in severe climatic conditions, eg under unfavorable and changing temperature range, under stress mechanical conditions, with large and variable range of vibrations such as

-2CZ 32847 U1 is characterized by conditions in aerospace and aeronautics.

Advantageously, the control lever according to the present invention is provided with four pivot joints arranged one above the other in two pairs, each pairs of pivot joints having a common pivot axis. the pairs of the draw rods are located and the pairs are opposed to each other. The control lever is coupled by means of these four linkages to four cams arranged in two pairs of cams opposite one another, to which the linkages are connected by means of four pivoted couplings arranged one above the other in two pairs. Each pair of these superposed pivoting joints of the linkages has a common axis of rotation of the pivoting joints. The advantage of this arrangement of the components in opposed pairs with the same number of oppositely oriented pivot axes is that it compensates for the clearances in these pivot joints, and thus the pivoting of the cams in the closed position is independent of these clearances of the pivot joints.

It is also preferred that the locking mechanism comprises three connecting pillars, namely two outer pillars, between which is located an inner pillar on which the operating lever is rotatably mounted. A pair of cams with stop teeth and tines are attached to each outer post. A pair of rods are attached to each pair of cams with their outer ends. This design with connecting columns represents an undemanding manufacturing variant for holding both the control lever and the cams.

The most preferred embodiment of the present invention is a retractable and retractable device having a locking mechanism having an axis of rotation of the actuating lever positioned centrally between the axes of rotation of opposing cams, wherein the axis of rotation of the actuating lever simultaneously lies in a central plane perpendicular to the plane defined by cams. The locking mechanism has gear rods of the same length. This arrangement represents an optimal and almost ideal constructional solution that provides symmetry not only in clearances but also in the geometrical arrangement of the individual components. The axis of rotation of the lever is located in the symmetry plane of the locking mechanism and substantially of the entire insertion and withdrawal device according to the present invention. Another great advantage is the possibility of using substantially identical rods on both sides of the locking mechanism, thereby greatly improving and ensuring correct and consistent cam rotation on both sides of the locking mechanism. In addition, identical rods represent a great simplification of production due to the use of fewer different parts. A great advantage is the easier pulling of the plug-in element from the guide frame by means of the operating lever, compared to CZ 304 640 B6.

Advantageously, the locking slider includes a locking element for locking the actuating lever in its closed position, which is located between the inner post and the outer post on the side of the actuating lever in the closed position, formed as a snap beak. The locking slider can be connected to a stop via a spring. The locking slider can be provided with a protective protrusion located between the snap beak and the inner column. An advantage of the locking slider according to this technical solution is that the spring stop ensures automatic snapping and secure holding of the snap beak, thereby securing the control lever in its closed position. A further advantage is provided by a protective projection which prevents destructive overload of the spring. The advantage of the finger grip is that it is positioned between the inner and outer pillars at a distance from the protrusion that ensures that the operator's hand is not injured by the lever opening when the locking slider is pulled.

Clarification of drawings

A non-limiting embodiment of an insertion and withdrawal device for coupling / disconnecting the optical and / or electrical connectors according to the present invention is described in detail in the exemplary embodiments and explained in more detail in the accompanying schematic drawings.

-3 GB 32847 U1

An optimum symmetrical solution of the male and female device according to the present invention is shown in the attached figures 1, 2, 3, 3a, 4, 5, 6, 6a, 6b, 7, 7a, 7b, 8, 8a, 8b, of which:

FIG. 1 shows the plug-in element in an axonometric side-front view from the side of the male and female locking mechanism, FIG. 2 shows the plug-in element in an axonometric side-rear view of the connector housing; Fig. 3a is a retractable and retractable locking mechanism in axonometric view and in the locked position; Fig. 4 is a retractable and retractable locking mechanism in top view in the locked condition; Fig. 5 guide frame in axonometric side-front view; Fig. 6a detail A of Fig. 6, Fig. 6b a schematic representation of the connector in the disconnected state to Fig. 6, Fig. 7 a plug-in element with a guide frame in a top view in the retracted state; 7a detail B of FIG. 7, FIG. 7b a schematic representation of the connector connection in the inserted state to FIG. 7, FIG. 8a detail C of FIG. 8, and FIG. 8b a schematic representation of the connector connection in the locked condition of FIG. 8.

The asymmetrical solution of the insertion and withdrawal device according to the present invention is shown in the attached figures 9, 9a, in which Fig. 9 shows the insertion and withdrawal detent mechanism in axonometric view and in the open state, and Fig. 9a insertion and withdrawal detent and in the locked closed state.

Examples of technical solutions

Example 1 (Figs. 1, 2, 3, 3a, 4, 5, 6, 6a, 6b, 7, 7a, 7b, 8, 8a, 8b)

1 and 2, there is shown a particular exemplary embodiment of a plug-in element 10 to whose front wall 103 a symmetrically disposed locking and retracting locking mechanism 15 is attached.

The plug-in element 10 is substantially rectangular. It comprises an upper lid 101 and an opposing bottom wall 105, a front wall 103 and an opposed rear wall 104, and two opposing side walls 102. In a particular exemplary embodiment, the lid 101 and the bottom wall 105 have dimensions of 100 mm x 100 mm, height of the front wall 103, rear wall 104 and side walls 102 is 30 mm.

A connector housing 9 is fastened to the rear wall 104 of the plug-in element 10. In the connector housing 9 there are, in the exemplary embodiment of Figure 2, five holes 18. Each hole 18 houses one connector insert that includes optical and / or electrical connectors. The optical connector 8 consists of a connector body, an optical fiber ferrule 16 and a connector spring 17, as shown, for example, in Figure 6b.

As can be seen from Figures 1 and 2, a particular exemplary embodiment of the plug-in element 10 has each of its side walls 102 provided with a guide groove 14 on the outside.

-4GB 32847 U1

The plug-in element 10 is inserted into a guide frame 11, which is shown in FIG. 5 in an exemplary embodiment.

The guide frame 11 is rectangular. It has two opposing side walls 112 which, in the exemplary embodiment of FIG. 5, are connected at both ends to each other by four connectors 113, 114, two superimposed front connectors 113 facing the front edges 115 and two superimposed rear edges. the connectors 114 facing the rear wall 116 of the guide frame 11. The front ends of the side walls 112 represent the front edges 115. A connector housing 117 is attached to the rear wall 116 of the guide frame 117. In a particular exemplary embodiment, the guide frame 11 has 140 mm side walls 112; height 40 mm. The rear wall 116, front and rear connectors 113, 114 have a width of 110 mm.

In the embodiment of FIG. 5, each side wall 112 of the guide frame 11 in its front portion, facing the front edge 115, is provided with two superposed support holes 12 for receiving the support elements, in the exemplary embodiment of the support tips 4 of the locking member 15 10. In an exemplary embodiment, the two side walls 112 of the guide frame 11 are provided on their inner walls with a rail 13 which is shaped to fit into the guide groove 14 of the plug-in element 10.

3, 3a and 4. The insertion and withdrawal arresting mechanism 15 according to the present invention each comprises three connecting posts, two outer posts Ύ_, Ύ \, between which an inner pillar 7i is positioned. 1. In an exemplary specific embodiment of an optimum symmetrical configuration, the inner post 7i is located in the central plane 22c.

The illustrated locking mechanism 15 comprises three connecting columns 7i, 7 ', 7 through which the control lever 1 and the cams 22 are rotatably mounted to the front wall 103 of the plug-in element 10. The inner post 7i thus forms the axis 20 of the rotation of the control lever 1. for pivotally connecting the control lever 1 to the front wall 103 of the plug-in element 10. The connecting column 7 and 7 respectively form the axis of rotation 21/21 of the cams 22 and 2 respectively and serve to rotatably connect the respective cams to the front wall 103 of the plug-in element.

The locking mechanism 15 according to the present invention comprises four elongate support gear rods 52, 5. The inner ends of the rods 52, 522 are rotatably attached to the actuating lever 1 through their pivotal connections to the pivot axes 242, 24. The outer ends of the rods 52, 5 are pivotably attached to the cams 22, 2 through their pivotal joints with the pivot axis 232, 23.

In an exemplary specific embodiment of an optimum symmetrical configuration, the rods 52, 522 are equally long and of identical shape.

The control lever 1 is in the "open position" when it forms an angle of about 90 ° with the front wall 103 of the plug-in element 10. The control lever 1 is in the " closed position " when the control lever 1 forms an angle of about 0 [deg.] With the front wall 103 of the plug-in element 10. The control lever 1 is shaped so that its outer free end securely locks the closed position.

Each cam 22, 2 is provided with two protrusions, a projection that extends beyond the width of the plug-in element 10 when the control lever 1 is open, and a projection that extends beyond the width of the plug-in element 10 when the lever 1 is closed. 4.

The insertion and withdrawal locking mechanism 15 according to the invention is provided with a locking slider 6 which is located in the groove of the front wall 103 of the plug element parallel to the plane 22. The plane 22 corresponds to the plane determined by the axes 21 /, 21 of cams 22, 222. The locking slider 6 is provided on the side of the locking mechanism 15 in the closing direction of the actuating lever 1 with a snap beak 64 and a protrusion 61 located between the locking beak 64 and the inner post 7i, and on the opposite side

Between the locking slider 6 and the stop 65 of the plug-in element 10 is a spring 63.

The locking mechanism 15 comprises four cams 2 ^' which are located at both ends of the locking mechanism so that their axes of rotation 21 /, 21 are perpendicular to the bottom wall 105 of the plug-in element 10 and form a plane 22 substantially parallel to the front wall 103 Thus, the two cams 2 'with the pivot axis 21' are located one above the other in the closing direction of the control lever 1, while the other two opposing cams 2 with the pivot axis 21 are located one above the other in the opening direction of the control lever T In the exemplary embodiment of the optimum symmetrical arrangement, the cams 22, 21 are rotated at the same distance from the plane 22c that is perpendicular to the plane 22.

The axis of rotation 20 of the control lever 1 lies in the plane 22c at a distance s from the plane 22. The distance s in a possible exemplary arrangement is about 3.6 mm.

Example 2 (Fig. 9, 9a)

Figs. 9 and 9a show an alternative asymmetrically arranged insertion and withdrawal arresting device 15, which differs from Example 1 in that in the arresting mechanism 15 the axis 20 of the control lever 7 is positioned between opposed cams 2, 2 asymmetrically, and the length of the pairs of opposing rods 52, 5 is not the same. In one possible alternative embodiment, the locking mechanism 15 shown in Figs. 9, 9a, in Fig. 9 in the "open position", in Fig. 9a in the "closed position" of the control lever 1.

In FIG. 9, the operating lever 1, shown in the open position, is situated outside the symmetry of the locking mechanism 15. Its pivot axis 20 is located closer to the pivot axis 21 of the pair of cams 222, the upper and lower cams 222 arranged one above the other. to the opposing pivot axis 21 'of a pair of cams 2 / upper and lower cams 2 / arranged one above the other. The pair of rods 52, the upper and lower rods 52, is longer than the opposed pair of rods 5, the upper and lower rods 522.

In Fig. 9a this unsymmetrical grip of the control lever 1 is shown in the closed position on the inner post 7i. In this possible particular asymmetrical arrangement of the insertion and withdrawal device, the distance (not shown) is about 2 mm, where s is the distance of the plane (not shown) 22 determined by the pivot axes 21/21 from the opposing cams 22,2 from the pivot axis 20

Although this is an asymmetrical arrangement of the locking mechanism 15, this construction also shows better results with respect to the closest prior art according to CZ 304 640 B6, in particular in terms of improved controllability of the device.

The plug-in and pull-out device for connecting / disconnecting the optical and / or electrical connectors 8 according to the present invention described in Examples 1 and 2 operates in three phases when inserting the plug-in element 10 into the guide frame 11 and in one phase.

In the first phase, one insertion element 10 is first guided and subsequently pushed into one guide frame 11. In this insertion, the control lever 1 is fully open and the guide grooves 14 of the insertion element 10 are guided by rails 13 on the inner side walls 112 of the guide frame 11. ends with an impact of the stop teeth 3 on the leading edges 115 of the guide frame 11 of FIG. 6.

In the second phase, after the stop elements 3 have been hit on the leading edges 115 of the guide frame 11, the cams 22, 222 are twisted and this movement is transmitted to the control lever 1 via the rods 52, 5 and thereby automatically rotates in the closing direction. At the same time, when turning the cams 22,

-6GB 32847 U1

2 '' their spikes 4 fit into the holes 12 in the side walls 112 of the guide frame 11 of Figure 7. Figure 6 schematically illustrates the force Fi that the operator pushes on the control lever 1 when retracted, which is transferred to the support spikes by lever 4, which then acts on the front of the apertures 12 to result in a force F F that will more easily help to overcome the resistance caused by either the spring of the optical connectors 8 or the frictional force of the electrical connectors. It can be stated that for forces Fi and F ?, the following relation holds:

F2 = ax (2x Fi / b), where Fi is the force exerted by the operator, F2 is the resulting plug-in force, and is the radius of rotation of the control lever 1 and b is the radius of rotation of the support tip 4. the physical contact of the optical and / or electrical contacts also occurs in the phase.

In the third phase, the control lever 10 by impacting the snap beak 64 moves the locking slider 6 away from the stop 65, and by means of the spring 63 the locking slider 6 returns to lock the operating lever 1 in the closed position. Snap-in snap-in closure 64 of the actuating lever 1 represents a secured connector connection as seen in Figures 8, 8b. In particular, in Figure 8b, the compression of the springs 17 which provide a functional optical connection can be seen.

Extending the plug-in element 10 is to disconnect the plug connection by sliding the plug-in element 10 from the guide frame 11 by allowing the operator to overcome the spring force 63 and frictional force between the beak 64 and the inner end of the lever 1 by the finger grip 62 and Lowering the protrusion 61 hits the inner pillar 7i to prevent the spring 63 from overstretching. Moving the locking slider 6 unlocks the control lever LV in the case of electrical connectors, during this phase, relatively high force must be exerted to eject the electrical pins. Therefore, there is a special shape of the rear edges of the support tines 4 which, when opening the control lever 1, pushes through the lever transmission against the rear of the openings 12, which helps to eject the electrical pins from their sockets. After the prongs 4 have fully extended from the apertures 12, the actuating lever 1 is perpendicular to the front wall 103, and due to its position in the central plane of the plug element 10, the extension phase can simply be completed by pulling it.

The described exemplary embodiments of the insertion and withdrawal device are proven and advantageous in the long term and represent an optimal number of components and their optimal arrangement within one another within the scope of the claims. These exemplary embodiments of the invention are not exhaustive and other combinations and variants within the scope of the claims are possible.

E.g. the insertion member 10 and the guide frame 11 may have other dimensions and shapes than those shown in the exemplary embodiments, may resemble a cube shape, or some walls of the insertion member 10 and / or the guide frame 11 may be square in shape, or may be taller height than width.

Both of these exemplary solutions utilize one control lever 1. It is possible to use several control levers 1 within the scope of the claims, eg placed one above the other, which has also been tested in development. This solution brings more components, a certain danger of instability and more complicated control and securing the closed position.

Both described embodiments use four portable draw bars 52, 5, four cams 22, 22- four stop teeth 3 and four support spikes 4 arranged one above the other in opposite pairs, which has proved to be a very advantageous embodiment of the device according to this technical solution. There is also a solution to the use of only two portable draw bars 52, 52, two cams 22, 222, two stop teeth 3 and two support spikes 4, which means less structural elements but a deterioration in the maneuverability and stability of the device. Conversely, a greater number of these structural elements, eg arranged in several pairs one above the other, which has also been tested in the course of development,

A large number of structural elements which do not substantially contribute to greater stability of the device or to improved manageability.

Industrial applicability

Plug-in and eject devices for connecting / disconnecting optical and / or electrical connectors 8 can be used in any industry, such as data and telecommunications links, aerospace, space, rail and shipping, energy, mining and chemical industries, etc., where it is necessary to provide for rapid replacement of the plug-in elements 10 with optical and / or electronic components, wherein the connections between the plug-in element 10 and the guide frame 11 are optical and / or electrical connectors 8 suitable for rear plane plug-in / pull-out elements 10 such as connectors according to EN4165.

PROTECTION REQUIREMENTS

Claims (7)

Insertion and withdrawal device for connecting and disconnecting optical and / or electrical connectors, comprising a guide frame (11) into which it is inserted and from which a plug-in element (10) is inserted by means of grooves (14) and rails (13); the guide frame (11) is provided with support holes (12) in the side walls (112); a locking mechanism (15) is attached to the front wall (103) of the plug-in element (10), which is equipped with a control lever (1), gear rods (5), cams (2) with support spikes (3) and stop teeth (4) and a locking slider (6) with a locking element, characterized in that the locking mechanism (15) a) is equipped at both its ends with cams (2 ', 2 ”) with axes of rotation (21', 21), while rotating cams (2 ', 2), each with a stop tooth (3) and a support tip (4), they are coupled to a rotatable control lever (1) positioned therebetween by means of gear rods (5 ', 5' '); b) has an operating lever (1), the pivot axis (20) of which is located between and parallel to the pivot axes (2121) of the cams (2 ', 2), and the pivot axes (2Γ, 21') of the cams (2 '); 2) define a plane (22) at a distance (s) from the axis of rotation (20) of the control lever (1), the distance (s) representing a perpendicular line between the plane (22) and the axis of rotation (20) of the control lever (1); and c) is provided with a locking slider (6) provided with a finger grip (62) on the side facing the open position of the control lever (1) and on the opposite side with a locking element to secure the closed position of the control lever (1) to connect the optical and / or electrical connectors ( 8). Insertion and withdrawal device according to claim 1, characterized in that the operating lever (1) d) is provided with four pivot joints arranged one above the other in two pairs, each pair of pivot joints having a common pivot axis (24 ', 24 ”), while four gear linkages (1) are attached to the control lever (1) by means of these pivot joints ( 5 ', 5 ") arranged in two superposed pairs of linkages (5', 5"), and the pairs are opposed to each other; and e) is coupled by means of these four links (5 ', 5 ”) to four cams (2', 2”) arranged in two superposed pairs of cams (2 ', 2 ”) opposite each other to which the links ( 5 ', 5 ”) connected by four pivot joints arranged one above the other into two pairs, each pair of these one above the other 32847 U1 arranged pivoting joints of the linkages (5 ', 5) have a common pivotal axis (2323) of pivoting joints. Insertion and withdrawal device according to claim 1, characterized in that the locking mechanism (15) comprises: three connecting posts (7 ', 1, 7i), two outer posts (7', Τ '), between which the inner post (7i) is located, the control lever (1) being rotatably mounted on the inner post (7i) , and to each outer post (7 ', Τ') a pair of cams (2 ', 2) is secured with stop teeth (3) and support tips (4). Insertion and withdrawal device according to claim 1, characterized in that the locking mechanism (15) a) has a pivot axis (20) of the control lever (1) located midway between the pivot axes (2Γ, 21) of opposing cams (2 ', 2), while the pivot axis (20) of the control lever (1) simultaneously lies in the central plane ( 22c), which is perpendicular to the plane (22) defined by the axes of rotation (21 ', 21) of opposing cams (2', 2); and (b) has transmission linkages (5 ', 5) of the same length. Insertion and withdrawal device according to claim 1, characterized in that the locking slider (6) has a locking element for securing the control lever (1) in its closed position, located between the inner column (7i) and the outer column (7 '). 7) on the side of the control lever (1) in the closed position, formed as a snap beak (64). Insertion and withdrawal device according to claim 1, characterized in that the locking slider (6) is connected to the stop (65) via a spring (63). Insertion and withdrawal device according to claim 5, characterized in that the locking slider (6) is provided with a protective projection (61) located between the snap beak (64) and the inner column (7i).